Asymmetric Aperture for Eyetracking

ABSTRACT

An asymmetric aperture device for a camera is provided that improves light gathering properties by increasing both the light gathering opening of the aperture and the number of light producing light sources placed on the aperture. An asymmetric aperture design is provided that utilizes a significantly larger portion of the camera lens. The tradeoff between the competing objectives of maximizing camera depth of field and maximizing the production of useful focus-condition information within the camera image is optimized. More illumination is provided without significantly increasing the lateral size of the illuminator pattern.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a divisional of U.S. patent application Ser. No.15/345,784, filed Nov. 8, 2016, which is a divisional of U.S. patentapplication Ser. No. 14/634,410, filed Feb. 27, 2015, now U.S. Pat. No.9,510,753, which claims the benefit of U.S. Provisional PatentApplication No. 61/945,551, filed Feb. 27, 2014, and U.S. ProvisionalPatent Application No. 61/945,546, filed Feb. 27, 2014, the content ofall of the above is incorporated by reference herein in theirentireties.

INTRODUCTION

The present invention relates to systems for determining the focuscondition of a lens, controlling the focus of the lens, finding a rangeto an object, and reducing the size of eyegaze tracking or eyetrackingdevices. Note that the terms “eyegaze tracking” and “eyetracking” areused interchaneagably throughout this application.

The terms eye tracking and eyegaze tracking include, but are not limitedto: recognizing an eye and features of an eye within an image, thefeatures of the eye including, including, for example, the pupil, iris,sclera, eyelids, canthi, and corneal reflection(s) of light(s) projectedonto the eye; measuring the coordinate location and image dimensions ofan eye and its features within an image; computing the locations of thephysical eye and its features in 3-dimensional space, where the eye'sspatial computations are derived from the eye image measurements;computing the angular orientation of an eye in space, based, forexample, on the relative locations of the eye features; computing thegaze line of an eye in space, e.g. the central visual line of the eyethat originates at the center of the foveola on the retina, passesthrough the primary nodal point of the eye, and projects out of the eyeinto space in accordance with the location and orientation of the eye inspace; and computing the location of the gaze point of an eye in space,e.g. the point in space where the gaze line intercepts a physical objectthat the eye sees, i.e. the location in space of the object thatprojects its image onto the foveola of the eye's retina.

In many imaging applications, it is often desired to focus a lens orother collector on an object and to maintain the lens sharply focuseddespite the object's longitudinal motion, i.e., motion along the opticalaxis of the lens. One such imaging application is eyetracking in whichan apparatus determines the point in space at which the eye is looking.In eyetracking, precise knowledge of the eye's 3D location in space isgenerally required in order to measure the eye's gazepoint in space, andmeasuring the longitudinal range, herein designated Z, from the camerato the eye is an essential element of measuring the eye location.

Prior eyetrackers are disclosed in U.S. Pat. No. 3,864,030 to Cornsweet;U.S. Pat. Nos. 4,287,410 and 4,373,787 to Crane et al.; U.S. Pat. No.4,648,052 to Friedman et al.; and in certain U.S. patent applications ofThomas E. Hutchinson, Ser. Nos. 07/086,809; 07/267,266, filed Nov. 4,1988; and Ser. No. 07/326,787. Those systems typically illuminate theeye with infrared light which is reflected from various parts of theeye, particularly the cornea and retina, to an imaging device such as avideo camera. The spatial relations between the reflections are used todetermine the gaze point. For example, the corneal reflection movesabout eighty micrometers per degree of eye rotation with respect to thepupil reflection.

From elementary geometry, it will be appreciated that the locationfinding accuracy of such trackers is heavily dependent on accuratelylocating the three-dimensional (3D) coordinates of the eye reflectionswith respect to the apparatus and with respect to each other. Thus, thegazepoint accuracy can be improved by improving the measurement of therange Z from the camera to the eye and maintaining the camera sharplyfocused on the eye. (To complete the full 3D location of the eye withinthe camera frame of reference, the lateral X,Y coordinates are typicallymeasured from the x,y location of the eye image within the camera'soverall 2D image.)

One (uncomfortable) way of keeping the camera focused is by preventingrelative motion of the eye and camera, e.g., by restraining the eye orhead of the user. Another way is by providing an autofocus mechanism tothe camera. (If lateral X,Y motions of the eye, i.e., motionsperpendicular to the optical axis, exceed the camera's instantaneousfield of view, a lateral tracking mechanism is also needed.) Theabove-cited U.S. patents describe two types of autofocus mechanismwhereby longitudinal eye displacements (along the Z axis) are detectedusing the corneal reflection of a light source. In the patent toCornsweet, a variable amplitude modulation due to motion of the source'simage formed between two chopper wheels is detected. In the patents toCrane et al., the difference in output between two detectorslongitudinally equidistant, when properly focused, from the source'simage is detected. U.S. Pat. No. 3,869,694 to Merchant et al. describesan improved eyegaze tracker that includes an ultrasonic positionmeasuring system that is used to adjust the focus of the tracker.

Other devices for focusing an imaging device on an eye are disclosed inU.S. Pat. No. 4,251,139 to Matsumura; U.S. Pat. No. 4,626,089 toTakahashi et al.; U.S. Pat. No. 4,673,264 to Takahashi; and U.S. Pat.No. 4,678,297 to Ishikawa et al. The patents to Ishikawa et al. andMatsumura disclose optical system focusing and alignment by projecting amark image onto the cornea and detecting the reflected mark image. Thepatents to Takahashi et al. and Takahashi disclose projecting a markimage into the eye and detecting the mark image reflected from theretina.

Those devices and other mechanisms such as multi-camera-parallax devicesare unsuitable for many gaze trackers and other applications becausethey typically require additional equipment and complex calibration, andmay not provide the required range measurement accuracy. In addition,they can excessively restrict the freedom of motion of the user.

Some video eyetrackers (illustrated in FIG. 3 for example) estimate therange to the eye by using multiple, widely separated illuminationsources (320) to produce multiple corneal reflections within thecamera's eye images. They then use the distance(s) between thosemultiple corneal reflection images to estimate the range from the eyefrom the camera. As the range to the eye increases, the distance betweenthe corneal reflections within the eye image decreases in inverseproportion to the range, thus providing information needed to estimatethe range. One key disadvantage of the widely-separated illuminatorapproach to measuring the range to the eye is that the width of theoverall eyetracking apparatus must be large in order to accommodate theilluminator separation. An advantage of the asymmetric aperture methodis that it allows the precise measurement of eye range without the useof widely separated illuminators, thereby reducing the overall size ofthe eyetracker apparatus. A second key disadvantage of the widelyseparated illuminators is that it depends on knowledge of the anatomicalproperties of the particular eye being tracked. It must know both theradius of the eye's corneal surface and the flattening properties of thecorneal surface toward its outer edges. The asymmetric aperture methoddiscussed here does not depend on this individual eye information. Therange measurement accuracy of the asymmetric aperture method dependsonly on the optical quality of the camera lens and aperture, both ofwhich are under full control of the eyetracker designer.

U.S. Pat. No. 4,974,010 to Cleveland et al. discloses a focus analysissystem comprising a) a point source whose focus condition is to bemeasured, b) a camera including a lens, an asymmetric aperture with anoncircular shape of distinguishable orientation and a sensor forcapturing the image formed by the lens the aperture, and c) an imageprocessor that analyzes the captured image and determines the focuscondition of the point light source based on the point source's image asshaped by the asymmetric aperture. This focus analysis system isparticularly useful in video eye trackers because the reflection of theeyetracker's illuminator off the corneal surface of the user's eye,commonly called the corneal reflection, is a virtual point light sourcethat is precisely tied to the location of the eye in space. Thusmeasuring the focus condition and range to the corneal reflection isequivalent to measuring the focus condition and range to the eye itself.This focus analysis system provides the required range measurementaccuracy for many gaze or eye trackers, without restricting the freedomof motion of users.

A key aspect of U.S. Pat. No. 4,974,010 to Cleveland is the shape of thecamera's asymmetric aperture that admits light to the sensor. As is wellknown in the camera art, a typical lens aperture is circular in itsperimeter shape. There are several reasons for this circular perimetershape. A) It is the easiest shape to manufacture. B) The circularperimeter is generally considered optimum from an optics perspective inthat a circle provides a maximum area (and thus allows the aperture tocapture a maximum amount of light) with respect to a minimum lateralextent of the aperture area. C) The circular shape maximizes the imagedepth of field and minimizes the image focus blur resulting from thefinite aperture size required to capture the numbers of photonsnecessary to generate a usable image.

The conventional circular aperture shape, however, does not imbuesufficient information into the camera image to be able to determine thefocus condition of an object being viewed. While the magnitude of anobject's focus blur does provide useful information as to the magnitudeof how far out of focus an object is, the blur from a circular apertureprovides no information about the direction of whether the camera isfocused too far or too near. The purpose of designing an optimumasymmetric aperture is to maximize the ability of the image processor tomeasure both the direction and magnitude of the focus conditionaccurately.

In camera optics, a lens “aperture” typically refers to the size, shapeand position of the optical opening that allows light from the outsideworld to pass through the lens and reach the camera sensor. Since anaperture opening is transparent, the opening itself typically containsno physical material, and the size, shape and position of the openingare physically implemented by the construction of opaque materialpositioned around the opening. For purposes of this discussion, anaperture “device” refers to the mechanical components of the surroundingopaque material used to configure the aperture “opening”.

FIGS. 1A and 1B illustrate examples of an asymmetric and a symmetricaperture (each including both the aperture openings and the aperturedevices), along with images of a point light source on the camera sensorsurface given (prior art). FIG. 1A illustrates an example of anasymmetric aperture. FIG. 1B illustrates a circular example of asymmetric aperture. FIG. 1C is a table illustrating the shapes of theimages of a point light source given: a) an asymmetric versus asymmetric aperture, and b) the lens being focused too near versus toofar. Note that the opaque portions 102 and 112 of the aperture devicesin FIGS. 1A and 1B are shaded, and the transparent aperture openings 101and 111 are shown in white. In all subsequent aperture drawings, theopaque portion of the aperture, e.g., the aperture device, are depictedin white, not shaded.

The shape of one asymmetric aperture 100 whose image from a point lightsource can be analyzed using the Cleveland method is shown in FIG. 1A.For comparison purposes, a conventional, symmetric, circular aperture110 is shown in FIG. 1B. The table in FIG. 1C illustrates the shapes ofthe images of a point light source given: a) an asymmetric versus asymmetric aperture, and b) the lens being focused too near versus toofar. From this table it can be seen that the shapes of the inverted(lens focused too far) and the non-inverted (lens focused too near)images of the point light source are distinguishable for the asymmetricaperture but indistinguishable for the symmetric aperture. Thus, withthe asymmetric aperture, it is possible to determine not only themagnitude of how far out of focus the lens is, but also the polarity(near versus far) of the focus error.

Note: The definitions of “symmetric” versus “asymmetric” apertures inthe context of measuring a lens's focus condition are clear from FIGS.1A and 1B. If the inverted shape of the aperture is indistinguishablefrom the uninverted shape, the aperture is symmetric, and provides noinformation regarding the near-vs-far polarity of the focus condition.If the inverted and non-inverted shapes are distinguishable, the shapeis asymmetric.

The particular “pie slice” shapes of the transparent openings 101 of theasymmetric aperture of FIG. 1A are constructed such that the invertedand uninverted images of the overall aperture pattern are maximallydifferent; i.e., when the overall centers of mass of the inverted anduninverted images are spatially aligned with one another, the individualtransparent-opening regions of the two patterns are maximally opposite.With the exception of the central region discussed later, transparentregions on one pattern correspond to opaque regions on the other. Thismaximal pattern difference maximizes the detectability of the invertedvs non-inverted feature of the image, thus increasing the imageprocessor's ability to resolve the focus condition when the camera is inits desired state of being well focused.

Though the small details of the shape of the transparent openings mayaffect the image processing function's precise ability to resolve finedifferences in the lens focus condition, it is obvious to one skilled inthe art that the more general shapes of the asymmetric aperture patternsdiscussed here provide the basic ability to measure focus condition andmaximize light utilization, and that minor variations in the exactperimeter shapes of the transparent openings do not circumvent theseinventions.

Note that the asymmetric aperture of FIG. 1A is opaque at the center.(As discussed later and shown in FIG. 5, the center is opaque because anon-axis illuminator (not shown) is located there.) One drawback of this“closed-center” asymmetric aperture design is that it blocks a large,central portion of the camera lens, thus blocking a large percentage ofthe light reaching the camera sensing means, and underutilizing the mostoptically useful center portion of the lens.

It is also well known in the camera art that the center of the apertureis typically aligned with the center of the camera lens to minimize thesize (i.e., diameter) of the lens required to make full use of theavailable aperture.

In contrast to the circular design of typical camera apertures, theasymmetric aperture method noted in U.S. Pat. No. 4,974,010 to Clevelandutilizes non-symmetric aperture shapes to generate image features thatconvey focus-condition information about objects the camera is viewing.Also as noted above, when designing asymmetric apertures there is atradeoff between image depth of field and focus condition information.

It is also well known in the video eyetracking art that the level ofillumination the eyetracker apparatus projects onto the eye must besufficient to produce a high quality image of the eye. Light emittingdiodes (LEDs) are often used to provide this illumination.

Reducing the size of eyetracking devices is critical to meet emergingneeds for incorporating eyetrackers into small computer devices,particularly handheld devices such as smart phones. During typicalusage, handheld devices move considerably with respect to a person'shead, so maintaining a sufficiently high quality image of the user'seye(s) to measure his gaze accurately is a difficult challenge. One wayto obtain such high quality eye images is to utilize telephoto lensesfitted with motorized gimbal mechanisms to keep the eyetracker camerapointed at and focused on the user's eye(s). In this discussion,motorized gimbal mechanisms in eyetracking devices are calledeyefollowers, where eyefollower gimbals can include camera pan/tiltdrives, camera autofocusing mechanisms, and camera zoom controls.Currently, the motorized gimbal mechanisms of eyefollowers are toolarge, heavy and expensive to be built into handheld devices where itwould be desirable to incorporate eyetrackers.

BRIEF DESCRIPTION OF THE DRAWINGS

The skilled artisan will understand that the drawings, described below,are for illustration purposes only. The drawings are not intended tolimit the scope of the present teachings in any way.

FIGS. 1A and 1B illustrate examples of an asymmetric and a symmetricaperture (each including both the aperture openings and the aperturedevices), along with images of a point light source on the camera sensorsurface given (prior art).

FIG. 1C illustrates the shapes of the images of a point light sourcegiven: a) an asymmetric versus a symmetric aperture, and b) the lensbeing focused too near versus too far.

FIG. 2 is a schematic diagram showing an eyetracker with a singleilluminator (prior art).

FIG. 3 illustrates an eyetracking camera configuration that uses widelyseparated illuminators to produce multiple corneal reflections fromwhich the range from the camera to the eye can be estimated (prior art).

FIGS. 4A-4C, reproduced from U.S. Pat. No. 4,974,010 to Cleveland,illustrate the ray-trace optics of the inversion or non-inversion of theimage of a point source of light based on the lens being focused beforeor beyond the point source (prior art).

FIG. 5 illustrates a closed-center asymmetric aperture with threetransparent openings and one illuminator device mounted at the center ofthe lens (prior art).

FIG. 6 illustrates a closed-center asymmetric aperture with threetransparent openings and four illuminator devices, one illuminatormounted at the center of the lens and three mounted between the threetransparent openings, in accordance with various embodiments.

FIG. 7 is a front view of an open-center asymmetric aperture thatoptimizes both the opening of the aperture and the number of lightsources, in accordance with various embodiments.

FIG. 8 is a cross-sectional side view of an image detector that includesthe asymmetric aperture of FIG. 7, in accordance with variousembodiments.

FIG. 9 is a schematic diagram of a lens/aperture/illuminator assembly inwhich the aperture device and the illuminators are positioned in frontof the objective lens (prior art).

FIG. 10 is a schematic diagram of a lens/aperture/illuminator assemblyin which the aperture device and the illuminators are positioned in thesame plane as objective lens, in accordance with various embodiments.

FIG. 11 is a schematic diagram of a lens/aperture/illuminator assemblyin which the aperture device is positioned behind the objective lens, inaccordance with various embodiments.

FIG. 12 is a schematic diagram showing an eyetracker that includes amechanized gimbal, in accordance with various embodiments (prior art).

FIG. 13 is a block diagram that illustrates a computer system, inaccordance with various embodiments.

FIG. 14 illustrates an exemplary camera pan/tilt control mechanism withMEMS actuators used to control the viewing direction of the camera bycontrolling the pan and tilt angles of the camera's body/lens assemblywith respect to the eyefollower's chassis, in accordance with variousembodiments.

FIG. 15 illustrates an exemplary camera pan/tilt control mechanism withMEMS actuators used to control the viewing direction of the camera bycontrolling the pan and tilt angle of a mirror placed in front of thecamera lens, in accordance with various embodiments.

FIG. 16 illustrates an exemplary camera focus control mechanism with aMEMS actuator used to control the distance L between the camera lensplane and the camera image sensor, in turn providing control of thecamera focus distance D, in accordance with various embodiments.

FIGS. 17A and 17B show an example camera focus control mechanism with aMEMS actuator used to control the focus power of a variable focus-powerlens such as a liquid or elastic lens, in accordance with variousembodiments.

FIG. 18 illustrates an example of a lens with variable zoom, inaccordance with various embodiments.

Before one or more embodiments of the present teachings are described indetail, one skilled in the art will appreciate that the presentteachings are not limited in their application to the details ofconstruction, the arrangements of components, and the arrangement ofsteps set forth in the following detailed description or illustrated inthe drawings. Also, it is to be understood that the phraseology andterminology used herein is for the purpose of description and should notbe regarded as limiting.

DESCRIPTION OF VARIOUS EMBODIMENTS Eyetracker

In general, an eyetracker or eye gaze tracker is a device that is usedto determine where an eye is looking. Modern eyetrackers, sometimesreferred to as video eyetrackers, are camera-based devices that observea person's eyes and predict the point in space where the person islooking. This point in space is referred to as the gazepoint, forexample. The line connecting the fovea of the eye, the center of the eyepupil, and the gazepoint is referred to as the gaze line, for example.

FIG. 2 is a schematic diagram showing a typical eyetracker 200 without agimbal (prior art). Eyetracker 200 includes image detector or camera210, light source 220, and processor 230. Light source 220 illuminateseye 240, and camera 210 images eye 240. Processor 230 receives the imagefrom camera 210 and determines from the image a) the camera's focuscondition of the eye and b) the orientation and position of eye 240 inspace. Based on the position and focus condition of the eye within thecamera image, the processor is able to compute the 3-dimensionallocation and orientation of actual eye 240 within the camera body frameof reference. From the eye's 3-dimensional location and orientation inspace, the processor is able to compute the eye's gaze line 250 andgazepoint 260 in space.

Eyetracker 200 can include additional elements. For example, eyetracker100 can include one or more additional cameras (not shown) or one ormore additional optical devices (not shown) to determine the range fromcamera 210 to eye 240. Eyetracker 200 can also include a display (notshown) to determine the gazepoint in an image displayed by processor 230on the display.

Also, in FIG. 2 image detector or camera 210 and light source 220 areshown as separate components. In various embodiments, image detector orcamera 210 can include light source 220.

FIG. 3 illustrates an eyetracking camera configuration 300 that useswidely separated illuminators 310 and 320 to produce multiple cornealreflections 315 and 325 from which the range from the camera 330 to theeye 340 can be estimated.

FIGS. 4A-4C, reproduced from U.S. Pat. No. 4,974,010 to Cleveland,illustrate the inversion or non-inversion of the image of a point sourceof light based on the lens being focused before or beyond the pointsource. From the inversion or non-inversion of the image the range froma camera to an eye can also be estimated.

Improved Asymmetric Aperture

As described above, many devices for focusing an imaging device on aneye are undesirable for many gaze or eye trackers, because theytypically require additional equipment and/or measurement of theindividual user's eye parameters to calibrate the range-measurementfunction, and may not provide the required range measurement accuracy.U.S. Pat. No. 4,974,010 to Cleveland provides an asymmetric aperturethat can provide the range measurement accuracy required for eyetracking. A key drawback of the asymmetric aperture of FIG. 1A, however,is that it blocks a large percentage of the light reaching the camera'ssensing means. Another key drawback is that the single illuminator ispower limited in its ability to support eyetracking at longer ranges.

In various embodiments, the light gathering properties of an asymmetricaperture such as illustrated in FIG. 1A are improved by increasing boththe light gathering opening of the aperture and the number of lightproducing light sources placed on the aperture. One important objectiveof various embodiments is to provide an asymmetric aperture design thatutilizes a significantly larger portion of the camera lens. A second keyobjective of various embodiments is to optimize the tradeoff between thecompeting objectives of maximizing camera depth of field and maximizingthe production of useful focus-condition information within the cameraimage.

A third important objective of various embodiments is to provide moreillumination without significantly increasing the lateral size of theilluminator pattern. While it is well known in the eyetracking oreyetracking art to increase the amount of light by using multipleilluminators, the embodiments discussed here optimize the relativeplacement of the illuminators with respect to the eyetracker camera lensso as to maintain maximum resolution in the system's ability to resolvesmall differences in the lens focus condition.

Since a camera's image quality generally depends on a sufficient amountof light reaching the sensor, any aperture blockage that results fromconstructing asymmetries in the aperture shape (with respect to aconventional circular aperture) results in a requirement for increasedillumination of the eye (with respect to the amount of light requiredfor a circular aperture). Thus the asymmetric aperture of FIG. 1A, withits large blockage of the camera lens area, significantly increases theeyetracker's illumination requirement to obtain a high quality eyeimage. Also, it should be recalled, eyetracker illumination requirementsincrease with the range to the eye, so to increase the operational rangeof an eyetracker, it is generally necessary to increase its illuminationpower.

Multiple Illuminator Devices

One method for increasing the amount of light reaching a camera's sensoris to simply increase the power of the illuminator source. To generate ahigh quality camera image, however, it is required that the illuminatorprovide a uniform illumination over the area being photographed, andmany illuminators, including LEDs, that are designed to provide uniformillumination are often limited in the maximum power they can producefrom a single device. Thus, once the total illumination requirement fora camera exceeds the maximum power of a single illuminator device, itbecomes necessary to use multiple illuminator devices. In eyetrackingcameras it is generally desired to keep the size of the illuminatorpattern as small as possible, thereby keeping the size of the cornealreflection at the eye as close to a virtual point source as possible.Thus, when increasing the number of illuminator devices above one, it isdesired to keep the devices as close together as possible. Given acamera with the asymmetric aperture pattern of FIG. 1A, it is possibleto a) use multiple illuminator devices, b) keep the cluster ofilluminator devices small, and c) not increase the opaque blockage ofthe asymmetric aperture pattern—by placing up to three additionalilluminator devices in the opaque regions (later defined as “tabs”)between the individual transparent regions 101.

FIG. 6 illustrates a closed-center asymmetric aperture with threetransparent openings and four illuminator devices, in accordance withvarious embodiments. As shown in FIG. 6, a closed-center asymmetricaperture device for a camera has a) three transparent regions arrangedin a circular pattern around the optic axis of the camera and b) a setof four illumination devices, up to one located at the center of thecircle and three located around the circle between the three transparentregions.

Open Aperture Center

Note that the asymmetric aperture shape of FIG. 1A is opaque at thecenter. FIG. 5 illustrates a closed-center asymmetric aperture withthree transparent openings and one illuminator device mounted at thecenter of the lens. As illustrated in FIG. 5, one reason to block thelens center is that it may be desired to place the eyetracker'silluminator 503 at the center of the lens, so as to produce cameraco-axial illumination of the eye, which in turn produces the brightpupil effect.

Another method for improving the light-collection properties of theasymmetric aperture of FIG. 1A is to remove the opaque region at thecenter of the aperture. FIG. 7 is a front view of an asymmetric aperture700 with a transparent opening 701 that optimizes both the area of theaperture opening and the number of light sources, in accordance withvarious embodiments. In this open-center implementation, the asymmetricaperture 700 device consists of a) a single transparent opening, wherethe outer perimeter of the opening 701 is inscribed in an outer circle,and b) a set of three opaque areas, or “tabs” 704, that intrude into theouter circular perimeter. In preferred embodiments, the opaque intrusiontabs 704 are evenly, or approximately evenly, spaced around theperimeter of the opening, and the angular widths 705 of the tabs 704 areequal or approximately equal to the angular widths 706 of the apertureopening segments along the outer perimeter of the circle. Thisopen-center triangular aperture pattern 700 retains the key feature thatthe inverted and non-inverted images are highly distinguishable,particularly if the angular widths 705 of the opaque intrusion tabsmatch the angular widths 706 of the transparent opening segments. At thesame time, the open center of the lens allows the camera sensor tocollect considerably more light than closed-center aperture of FIG. 1A.

Multiple Illuminators with an Open-Center Aperture

The open-center design of aperture 700, of course, precludes theplacement of a single, coaxial illumination source at the center of thecamera lens. However, in various embodiments a set of three illuminators703 may be positioned very close to the lens center by installing themwithin the opaque intrusion tabs 704 as shown in FIG. 7. W. The threelight sources 703 are light emitting diodes (LEDs), for example.

The asymmetric aperture opening 701 produces a pattern that resembles ahub with three spokes. The hub and threes spokes can also be describedas a central lobe with three adjacent lobes. The three spokes oradjacent lobes of the opening provide the asymmetry with respect totypical spherical apertures. Although FIG. 7 shows only three spokes,one of ordinary skill in the art can appreciate that an asymmetricaperture can include any odd number of spokes or adjacent lobes, sincean odd number of spoke lobes provides a distinguishable image shape wheneither inverted or uninverted, as occur when the lens is focused closeror farther than a point source image such as a reflection of anilluminator off an eye's corneal surface. The inverted or uninvertedimage of a point source, based on the camera's being focused too far ortoo near, is illustrated in FIGS. 4A-4C (reproduced from FIG. 3 of U.S.Pat. No. 4,974,010 to Cleveland). Specifically, FIGS. 4A-4C illustratethe ray-trace optics of the inversion or non-inversion of the image of apoint source of light based on the lens being focused before or beyondthe point source. Similarly, one of ordinary skill in the art canappreciate that an asymmetric aperture can include any odd number oflight sources that can be placed in the opaque intrusion-tab regions 704of the aperture.

By placing light sources 703 within the opaque intrusion-tab regions ofthe asymmetric aperture, the center of asymmetric aperture opening 701can be left open, optimizing the amount of light that can pass throughthe aperture opening 701. By using more than one light illuminationsource, the amount of light that can reach the camera lens sensor isalso increased.

Longitudinal Location of the Asymmetric Aperture

FIG. 8 is a cross-sectional side view of an image detector that includesthe asymmetric aperture of FIG. 7, in accordance with variousembodiments. Specifically, image detector assembly 800 includes a) anasymmetric aperture device 802, with an asymmetric aperture opening suchas 701 shown in FIG. 7. Image detector assembly 800 further includes b)an objective lens element 810 (also referred to as objective lens), c)an exit lens element 820, and d) an optical filter 830 that may be usedto minimize image noise from ambient light sources. Image detectorassembly 800 further includes e) an image sensor 840, f) a printedcircuit board 850 that mechanically and electronically supports thecamera sensor 840, and g) illuminators 803. Image detector assembly 800further includes h) electrical leads 870 that supply power from thecircuit board 850 to the illuminators 803, and i) a lens-barrel frame860 that mechanically houses the lens elements 810, 820, optical filter830, printed circuit board 850 of the camera, illuminators 803, andasymmetric aperture device 802. Asymmetric aperture device 802 providesthe asymmetric and, therefore, orientation distinguishable imagereceived by image sensor 840.

In FIG. 8, asymmetric aperture device 802 is shown in front of objectivelens element 810. Asymmetric aperture device 802, however, can be placedin an infinite number of locations along the longitudinal axis oflens-barrel frame 860. For example, asymmetric aperture device 802 maybe placed a) out in front of objective lens element 810, as indicated bythe location shown as 802 in FIG. 8, b) within objective lens element810, as indicated by location 812, or c) behind objective lens element810, as indicated by location 822.

In current implementations of cameras with asymmetric apertures,asymmetric aperture device 802 is located out in front of objective lenselement 810, at the location shown as 802 in FIG. 8. This location outin front of objective lens element 810, however, presents twolimitations. First, placing the aperture outside the lens extends theoverall length of the camera apparatus, particularly if the illuminatorsare also mounted on the aperture device outside the objective lens.Second, from the optical standpoint of the point light source projectingthe shape of the aperture onto the camera sensor, the optimumlongitudinal location for the aperture opening resides at the planewhere the lens's focus refraction occurs, i.e., at the longitudinalplane where the light rays bend the most. (See the location of thelight-ray refraction in FIG. 4.) As long as the light source lies on thecamera's central longitudinal axis, there is no distortion of theprojected aperture shape—as long as the aperture device is centered onand located along the camera axis. As the point source moves off axis,however, the projected aperture shape as seen on the camera sensordistorts in proportion to two factors: a) the off-axis angle of thepoint source within the camera field of view, and b) the longitudinaldistance between the aperture plane and the lens's primary refractionplane. Thus, to accurately measure the focus condition for point-sourceobjects throughout the camera's angular field of view, the optimumlocation for the aperture-device plane is the longitudinal center of theobjective lens.

FIG. 10 is a schematic diagram of a lens/aperture/illuminator assembly1010 in which asymmetric aperture device 1002 and illuminators 1003 arepositioned in the same plane as objective lens element 1020, inaccordance with various embodiments.

In one embodiment of this invention, the plane of the asymmetricaperture device is embedded within the objective lens of the camera,i.e., the opaque material forming the lens aperture is embedded withinthe body of the camera's objective lens. As shown in FIG. 10, asymmetricaperture device 1002 is embedded in an objective lens 1020. Incomparison, FIG. 9 is a schematic diagram of a prior artlens/aperture/illuminator assembly 900 in which aperture device 902 andilluminators 903 are positioned in front of objective lens element 920.As shown in FIG. 9, prior art assembly 900 also includes optical filter930, image sensor 940, and printed circuit board 950.

Minimizing the Length of Lens/Aperture/Illuminator Assembly

In addition to showing asymmetric aperture device 1002 being embedded inthe camera's objective lens element 1020, FIG. 10 also illustratesilluminators 1003 mounted at a longitudinal position such that the frontof illuminators 1003 do not extend forward of the front of objectivelens element 1020, in accordance with various embodiments. Thisilluminator configuration, with the illuminators a) being close to oneanother in the camera lateral plane and b) existing behind the front ofobjective lens element 1020 along the longitudinal axis, is useful forcases where it is desired to minimize the overall size of the cameraequipment.

As can be seen in FIG. 10, however, illuminators 1003 exist within thephysical volume of a conventionally designed objective lens. To positionilluminators 1003 in these optimal locations, it is necessary to removematerial from the objective lens to create space for the illuminators.In this discussion, the spaces cut out from what would otherwise be aconventional objective lens are called “lens cutouts.” The lens cutouts1005 are shown in FIG. 10 by dotted line. Though incorporating theselens cutouts in the objective lens may add to the lens production cost,the camera performance increases in measuring focus condition oftenjustify the expense.

In accordance with the discussion above, one embodiment of thisinvention is a camera employing a) illuminators, b) an objective lens,and c) an asymmetric aperture device with opaque intrusion areas,wherein lens cutouts are incorporated into the camera's objective lensat lateral locations corresponding to the illuminator locations. Thelens cutouts permit the physical location of the illuminators within thelens cutout volumes behind the front surface of the lens.

In some cases, it may not be practical or economically feasible to embedthe asymmetric aperture device within the camera's objective lens. Inthese cases, and where it is also desired to minimize the overall lengthof the camera equipment, the asymmetric aperture device may bepositioned behind the objective lens, as illustrated in FIG. 11, inaccordance with various embodiments.

FIG. 11 is a schematic diagram of a lens/aperture/illuminator assembly1100 in which aperture device 1102 is positioned behind objective lenselement 1120, in accordance with various embodiments. As shown in FIG.11, lens/aperture/illuminator assembly 1100 also includes optical filter1130, image sensor 1140, printed circuit board 1150, and lens cutouts1105 (illustrated by dotted line).

Though locating the asymmetric aperture device behind the objective lensmay avoid the cost of embedding the aperture device in the objectivelens, it is still necessary to include the lens cutouts in the objectivelens if the illuminators 1103 are not to be placed out in front of thelens.

In various embodiments, an open-center asymmetric aperture deviceincludes a single transparent opening and a set of opaque intrusionareas. An outer perimeter of the single transparent opening is inscribedin a circle and the set of opaque intrusion areas intrude into the outerperimeter of the inscribed circle.

In various embodiments, the set of opaque intrusion areas comprise a setof three opaque intrusion areas. For example, the three opaque intrusionareas are evenly or approximately evenly spaced around the outerperimeter of the single transparent opening. For example, the angularwidths of the three opaque intrusion areas are equal or approximatelyequal to the angular widths of the aperture-opening segments along theouter perimeter of the inscribed circle.

In various embodiments, the open-center asymmetric aperture devicefurther includes multiple light illumination sources located within theset of opaque intrusion areas.

In various embodiments, a method for fabricating an open-centerasymmetric aperture device is provided. A single transparent opening isinscribed in a circle. A set of opaque intrusion areas are made tointrude into the outer perimeter of the inscribed circle.

In various embodiments, a closed-center asymmetric aperture device for acamera includes a plurality of transparent regions arranged in acircular pattern around an optical axis of a camera and a set ofillumination devices. One illumination device is located at the centerof the circular pattern, and two or more additional illumination devicesare located around the circular pattern between the plurality oftransparent regions.

In various embodiments, the plurality of transparent regions comprisethree transparent regions.

In various embodiments, the set of illumination devices comprises a setof up to four illumination devices, and the two or more additionalillumination devices comprise three illumination devices.

In various embodiments, a method for fabricating a closed-centerasymmetric aperture device for a camera. A plurality of transparentregions arranged in a circular pattern are created around an opticalaxis of a camera. One illumination device is placed at the center of thecircular pattern, and two or more additional illumination devices areplaced around the circular pattern between the plurality of transparentregions.

A camera employing an asymmetric aperture device includes an objectivelens and an asymmetric opaque aperture device. The asymmetric opaqueaperture device includes a single transparent opening and a set ofopaque intrusion areas. An outer perimeter of the single transparentopening is inscribed in a circle. The set of opaque intrusion areasintrude into the outer perimeter of the inscribed circle.

In various embodiments, the asymmetric opaque aperture device isembedded within the objective lens of the camera.

In various embodiments, the asymmetric opaque aperture device is locatedout in front of the objective lens of the camera.

In various embodiments, the asymmetric opaque aperture device is locatedbehind the objective lens of the camera.

In various embodiments, the asymmetric opaque aperture device includesmultiple light illumination sources.

In various embodiments, a method for fabricating a camera employing anasymmetric aperture device is provided. The camera is made to include anobjective lens and an asymmetric opaque aperture device. The asymmetricopaque aperture device is made to include a single transparent openingand a set of opaque intrusion areas. An outer perimeter of the singletransparent opening is inscribed in a circle. The set of opaqueintrusion areas are made to intrude into the outer perimeter of theinscribed circle.

In various embodiments, a camera includes a plurality of illuminators,an objective lens, and an asymmetric aperture device with opaqueintrusion areas. Material is removed from the objective lens to createspaces for the plurality of illuminators. The spaces are lens cutouts.The lens cutouts are incorporated into the objective lens of the cameraat lateral locations corresponding to locations of the plurality ofilluminators, the lens cutouts permitting the plurality of illuminatorsto be located within a physical volume of the objective lens.

In various embodiments, the asymmetric aperture device is embeddedwithin the objective lens of the camera.

In various embodiments, the asymmetric aperture device is located out infront of objective lens of the camera.

In various embodiments, the asymmetric aperture device is located behindthe objective lens of the camera.

In various embodiments, the asymmetric aperture device comprisesmultiple light illumination sources.

In various embodiments, a method for fabricating a camera is provided.The camera is made to include a plurality of illuminators, an objectivelens, an objective lens, and an asymmetric aperture device with opaqueintrusion areas. Material is removed from the objective lens to createspaces for the plurality of illuminators. The spaces are lens cutouts.The lens cutouts are incorporated into the objective lens of the cameraat lateral locations corresponding to locations of the plurality ofilluminators, the lens cutouts permitting the plurality of illuminatorsto be located within a physical volume of the objective lens.

Free Head Motion

An important objective of many eyetrackers is to allow the user to movehis head freely while the eyetracker continues to track the user's gazewith high accuracy. Typical head motions involve moving (translating)the head side to side, up and down, and back and forth; and involverotating the head forward and back (pitching or nodding), rotating theface left to right (yawing or shaking), and rotating the head toward oneshoulder or the other (rolling). One method for minimizing head motionwith respect to an eyetracking device is to place the eyetracker deviceon the user's head, attached to a pair of glasses for example. In manyapplications, however, it is desired to position the eye eyetrackingdevice at a remote, off-head location. Accommodating head motion withrespect to the eyetracker platform is particularly relevant to theobjective of capturing high quality, high resolution eye images inremote eyetrackers.

To accommodate variable positions and orientations of the head withrespect to the eyetracker platform, non-head mounted, i.e. remote,eyetrackers may include mechanized gimbal devices to keep the eyetrackercamera(s) physically pointed at, focused on, and/or zoomed on the user'seye(s). As illustrated in FIG. 12, a motorized pan-tilt device, such asa gimbal 1215, may be used, for example, to keep the camera's viewdirection pointed at the eye or eyes; a focus motor (not shown in FIG.12) may be used to keep the eye(s) in focus; or a zoom motor (not shownin FIG. 12) may be used to keep a desired zoom condition on the eye(s).Eyetrackers that utilize such mechanical means to automatically point,focus and/or zoom their eyetracking cameras on the eyes are sometimesreferred to as eyefollowers.

Gimbal-Based Eyetracker (Eyefollower)

As described above, the motorized gimbal mechanisms of conventionaleyefollowers are too large, heavy, and expensive to be built intohandheld devices where it would be desirable to incorporateeyetrackering devices.

In various embodiments, the size, weight, and power consumption ofgimbal based eyetracking devices is reduced by usingmicroelectromechanical systems, commonly referred to as MEMS, to controlthe physical camera positioning and focusing functions. Theincorporation of MEMS into eyefollower architectures represents acritical advance in eyetracking technology because it enables theultimate miniaturization of eyefollower devices.

FIG. 12 is a schematic diagram showing an eyetracker 1200 that includesan eyefollower, in accordance with various embodiments. Eyetracker 1200includes camera 1210 (including camera body and camera lens), gimbal1215, and processor 1220. The eyefollower portion of eyetracker 1200includes, for example, a mechanical configuration comprising gimbal1215, and a motorized lens (not shown) for camera 1210 that implements avariable-focus range. The eyefollower portion of eyetracker 1200 mayalso include a motorized zoom capability (not shown) for camera 1210that implements a variable zoom. Note that camera 1210 can also includean illumination source (not shown).

In FIG. 12, the gimbal 1215 of eyetracker 1200 controls the yaw (pan)and pitch (tilt) of camera 1210, which, in turn, are used to follow auser's eye 1240 as the user moves his head and/or eye 1240 fromside-to-side and up and down, respectively. The motorized lens forcamera 1210 is used to follow the user's eye 1240 as the user moves hishead forward or backward, and it may also be used in the computation ofthe range from the camera to the eye based on a measurement of the lenslength required to put the eye in focus. (U.S. Pat. No. 4,974,010 toCleveland et al. discloses a focus analysis system comprising a) a pointsource whose focus condition is to be measured, b) a camera including alens, an asymmetric aperture with a noncircular shape of distinguishableorientation and a sensor for capturing the image formed by the lens theaperture, and c) an image processor that analyzes the captured image anddetermines the focus condition of the point light source based on thepoint source's image as shaped by the asymmetric aperture. This focusanalysis system is particularly useful in video eye trackers because thereflection of the eyetracker's illuminator off the corneal surface ofthe user's eye, commonly called the corneal reflection, is a virtualpoint light source that is precisely tied to the location of the eye inspace.) The motorized zoom for camera 1210 may be used to control thedesired size, i.e., pixel resolution, of the eye image within the cameraimage as the user moves his head forward and backward. Gimbal 1215 canbe optionally secured to display 1230, mechanically linking thecoordinate system of camera 1210 to display 1230, for example.

Though gimbal 1215 in FIG. 12 can be used to rotate the entire camera tocontinually point at the user's eye(s), it is also possible to rotate amirror placed in front of the camera lens so as to steer the camera'sview direction toward the eye, thus requiring the rotation of only asmall, light mirror rather than a generally larger and heavier cameraand lens assembly. U.S. Pat. No. 5,090,797 to Cleveland et al. disclosesa mirror control system that can be used in an eyetracker comprising a)a camera and with a lens, b) a pan/tilt mirror with motors to drive thepan and tilt angles, c) an image processor that processes the camera'simage of a user's eye and computes the location of the eye within thecamera image frame, d) a mirror command calculator that calculatespan/tilt commands required to keep the eyes within the camera image, ande) motor controllers that convert the pan/tilt commands to motor controlsignals that actuate the motors. Currently, gimbal implementationsinvolving either mirror rotation or full camera/lens rotation are toolarge and bulky for implementation in many applications. The size andweight of these eyetracker gimbal configurations are significantlyminiaturized by the use of MEMS, thus enabling many applications thatare not now practical.

The processor 1220 of eyetracker 1200 shown in FIG. 12 typicallyperforms several of the eyetracker functions required to measure aneye's gazepoint. First, it receives the image of the eye from theeyetracker camera. It then processes the eye image to detect the eyewithin the image and determine the location of the eye within the image.If the eyetracker has eyefollower capabilities, the processor alsoexecutes control loop algorithms required to keep the camera pointed at,focused on, and zoomed on eye 1240 as the user moves his head. Processor1220 also executes, for example, algorithms used to solve rigoroustrigonometric gazepoint tracking equations, referred to as “explicitraytrace algorithms.” These explicit raytrace algorithms are used toaccurately predict the user's gazepoint 1250 on display 1230, fullyaccommodating the variable camera geometry and the moving head and/oreye 1240. U.S. Pat. No. 7,686,451 to Cleveland discloses such explicitraytrace algorithms.

As discussed above, a key performance objective of most videoeyetrackers is to measure the coordinates of where a person is lookingwith a certain level of gazepoint tracking accuracy. To achieve a givendegree of accuracy, it is necessary that the eyetracking camera producesa high quality video image stream of the eye with spatial, illuminationand temporal resolutions sufficient to support the gazepoint calculationfrom the captured video images.

It is also an objective of many modern eyetrackers to permit evergreater freedom of user head movement while the eyetrackers continue totrack the gaze with equivalent or increasing accuracy. One approach toincreasing the volume of trackable head space is to increase a fixedcamera's 3-dimensional volume of view. To maintain gazepoint trackingaccuracy with a fixed camera, however, the increased field of view mustbe accompanied by a proportional increase in the number of pixels on thecamera image sensor, so as to maintain a high resolution of the camera'seye image.

Another approach to increasing the volume of trackable head space is toallow the camera to physically rotate, refocus and move, much the sameway live eyes do. A telephoto, narrow-field-of-view camera can produce ahigh resolution image of the eye with a comparatively small number oftotal sensor pixels, and freedom of user head movement is achieved byplacing the camera on a controlled pan/tilt gimbal that keeps thecamera(s) pointed at and focused on the user's eyes as the user moveshis head around with respect to the eyetracker platform.

Current implementations of gimbal-based eyetrackers typically utilizestepper motors and/or analog servo motors to rotate the camera body andfocus the lens. The use of these types of actuators has severaldisadvantages. Various embodiments minimize the size, weight, powerconsumption, cost, and noise of gimbal based eyetrackers by usingmicroelectromechanical systems, commonly referred to as MEMS, to controlthe physical camera positioning and focusing functions.

Computer-Implemented System

While computer processors perform the automated image processingfunctions within non-mechanized eyetrackers, they also execute the motorcontrol functions in gimbal-based eyetrackers. FIG. 13 is a blockdiagram that illustrates a computer system 1300, in accordance withvarious embodiments. Computer system 1300 includes a bus 1302 or othercommunication mechanism for communicating information, and a processor1304 coupled with bus 1302 for processing information. Computer system1300 also includes a memory 1306, which can be a random access memory(RAM) or other dynamic storage device, coupled to bus 1302 fordetermining base calls, and instructions to be executed by processor1304. Memory 1306 also may be used for storing temporary variables orother intermediate information during execution of instructions to beexecuted by processor 1304. Computer system 1300 further includes a readonly memory (ROM) 1308 or other static storage device coupled to bus1302 for storing static information and instructions for processor 1304.A storage device 1310, such as a magnetic disk or optical disk, isprovided and coupled to bus 1302 for storing information andinstructions.

Computer system 1300 may be coupled via bus 1302 to a display 1312, suchas a cathode ray tube (CRT), liquid crystal display (LCD), or3-dimensional display, for displaying information to a computer user. Aninput device 1314, including alphanumeric and other keys, is coupled tobus 1302 for communicating information and command selections toprocessor 1304. Another type of user input device is cursor control1316, such as a mouse, a trackball or cursor direction keys forcommunicating direction information and command selections to processor1304 and for controlling cursor movement on display 1312. This inputdevice typically has two degrees of freedom in two axes, a first axis(i.e., x) and a second axis (i.e., y), that allows the device to specifypositions in a plane.

A computer system 1300 can perform the present teachings. Consistentwith certain implementations of the present teachings, results areprovided by computer system 1300 in response to processor 1304 executingone or more sequences of one or more instructions contained in memory1306. Such instructions may be read into memory 1306 from anothercomputer-readable medium, such as storage device 1310. Execution of thesequences of instructions contained in memory 306 causes processor 1304to perform the process described herein. Alternatively hard-wiredcircuitry may be used in place of or in combination with softwareinstructions to implement the present teachings. Thus implementations ofthe present teachings are not limited to any specific combination ofhardware circuitry and software.

The term “computer-readable medium” as used herein refers to any mediathat participates in providing instructions to processor 1304 forexecution. Such a medium may take many forms, including but not limitedto, non-volatile media, volatile media, and transmission media.Non-volatile media includes, for example, optical or magnetic disks,such as storage device 1310. Volatile media includes dynamic memory,such as memory 1306. Transmission media includes coaxial cables, copperwire, and fiber optics, including the wires that comprise bus 1302.

Common forms of computer-readable media include, for example, a floppydisk, a flexible disk, hard disk, magnetic tape, or any other magneticmedium, a CD-ROM, any other optical medium, punch cards, papertape, anyother physical medium with patterns of holes, a RAM, PROM, and EPROM, aFLASH-EPROM, any other memory chip or cartridge, or any other tangiblemedium from which a computer can read.

Various forms of computer readable media may be involved in carrying oneor more sequences of one or more instructions to processor 1304 forexecution. For example, the instructions may initially be carried on themagnetic disk of a remote computer. The remote computer can load theinstructions into its dynamic memory and send the instructions over atelephone line using a modem. A modem local to computer system 1300 canreceive the data on the telephone line and use an infra-red transmitterto convert the data to an infra-red signal. An infra-red detectorcoupled to bus 1302 can receive the data carried in the infra-red signaland place the data on bus 1302. Bus 1302 carries the data to memory1306, from which processor 1304 retrieves and executes the instructions.The instructions received by memory 1306 may optionally be stored onstorage device 1310 either before or after execution by processor 1304.

In accordance with various embodiments, instructions configured to beexecuted by a processor to perform a method are stored on anon-transitory and tangible computer-readable medium. Thecomputer-readable medium can be a device that stores digitalinformation. For example, a computer-readable medium includes a compactdisc read-only memory (CD-ROM) as is known in the art for storingsoftware. The computer-readable medium is accessed by a processorsuitable for executing instructions configured to be executed.

The following descriptions of various implementations of the presentteachings have been presented for purposes of illustration anddescription. It is not exhaustive and does not limit the presentteachings to the precise form disclosed. Modifications and variationsare possible in light of the above teachings or may be acquired frompracticing of the present teachings. Additionally, the describedimplementation includes software but the present teachings may beimplemented as a combination of hardware and software or in hardwarealone. The present teachings may be implemented with bothobject-oriented and non-object-oriented programming systems.

Systems and Methods of Miniaturization

As described above, eye tracking systems have included largegimbal-based cameras or imaging devices for capturing images from one ormore eyes. Recently, camera lenses and imaging devices have gottensmaller, due to technological advances in areas including, but notlimited to, hand-held devices such as smartphones. As a result, a needhas developed to miniaturize or reduce the overall size of eyetrackingsystems along with their camera lenses and imaging devices.

Some eyetrackers, sometimes called eyefollowers, utilize additionalmechanical devices such as gimbals and autofocusing mechanisms to point,focus and zoom the cameras on user's eyes. These point, focus and zoomactuator devices within the eyefollower, which in many cases aresignificantly larger than the camera itself, also need to beminiaturized.

In various embodiments, an eyetracker that includes an eyefollower isminiaturized or made smaller by using microelectromechanical systems(MEMSs), also referred to as MEMS devices. MEMSs can also be referred toas micro-electro-mechanical, microelectronic, or microelectromechanicalsystems, micromachines, or micro systems technology (MST). MEMSs canalso include nanoelectromechanical systems (NEMS) and nanotechnology. Byproducing highly controllable, large amplitude electromagnetic forcesfrom small volumes of material, MEMSs can be used, for example, toreplace stepper motors, analog servo motors and complicated gear trainstypically used in conventional eyefollowers. The use of MEMSsignificantly reduces the size, weight, power consumption, cost andnoise of gimbal based eyetrackers, ultimately making it feasible toimplement head-free eyetracking in small, hand-held devices such assmart phones.

Pan/Tilt Control

To decrease the overall size of an eyefollower system, MEMSs are used invarious embodiments to position an eyetracker camera's view direction.As discussed earlier, pointing an eyetracker's camera's view directioncan be achieved either directly, by rotating the camera/lens assembly,or indirectly, by placing a pivoting mirror in front of the lens androtating only the mirror.

In embodiments where the whole camera (i.e., including the camera bodyand the camera lens) is rotated, the camera may be mounted on a pan-tiltgimbal platform, and a small gimbal platform may be fabricated usingMEMS devices.

Given that MEMS actuators are small, however, yet even smallereyefollower configurations can be implemented by attaching the MEMSactuators directly to the camera body, rather to a pan/tilt platformthat in turn supports the camera. FIG. 14 illustrates one embodiment1400 of an eyefollower pan/tilt control mechanism employing MEMS devicesto control the pointing direction of the camera body and lens, inaccordance with various embodiments. In this example, camera body 1401is attached to camera lens 1402 and the camera body is attached tocamera pivot point 1403 that is anchored to eyefollower chassis 1404. Alinear MEMS actuator 1405 a, 1405 b, attached at one end to eyefollowerchassis 1404, is attached at the other end to the side of camera body1401 at a longitudinal position forward of the camera pivot point 1404.The actuator's linear direction of travel 1406 is perpendicular to thecamera axis Z, resulting in an angular travel of the camera. There aretwo linear actuators: pan actuator 1405 a attached to one side of thecamera, whose motion results in the camera rotating in horizontal panplane 1407 a; and yaw actuator 1405 b attached to the top or bottom ofthe camera, whose motion results in the camera rotating in vertical tiltplane 1407 b. As eye 1410 moves side to side or up and down, actuators1405 a, 1405 b rotate camera body 1401 and lens 1402 to follow eye 1410.

FIG. 15 illustrates an embodiment 1500 of an eyefollower pan/tiltcontrol mechanism employing MEMS devices to steer the pointing directionof the camera by rotating a mirror 1510 located in front of lens 1502,in accordance with various embodiments. In this example, camera body1501 is attached to eyefollower chassis 1504 and camera lens 1502 isattached to camera body 1501. The position and angular orientation ofrotatable mirror 1510 is determined by three (3) attachment points.First, a mirror pivot point 1511 attached to one point on the mirror isanchored to eyefollower chassis 1504. Second, a pair of linear MEMSactuators 1512 a and 1512 b, each with one end attached to eyefollowerchassis 1504, are connected at their other ends to the second and thirdpoints on mirror 1510. The three (3) connection points are arranged in atriangular pattern such that the combined travels of actuators 1512 aand 1512 b result in mirror pan/tilt angles 1514 a and 1514 b requiredto reflect the camera's view direction Z toward eye 1510. In anembodiment, the nominal orientation of mirror 1510 is 45 degrees withrespect to the camera longitudinal axis, and the nominal direction ofthe two actuator travels are approximately perpendicular to the mirrorplane (as drawn in FIG. 15).

It should be noted that, in either the direct camera-controlconfiguration of FIG. 14 or in the indirect mirror-control configurationof FIG. 15, the two actuators need not be configured to control the panand tilt independently. As long as some combination of actuatorpositions provides access to all the desired pan and tilt orientations,any cross coupling between the control axes may be mathematicallydecoupled in the control algorithms implemented in the eyefollower'scomputer software. The use of decoupling in the control software allowssignificant freedom in the mechanical design of the actuator connectionpoints, resulting in further miniaturization of the overall eyefollowerpackage.

Focus Control

In various embodiments, MEMSs are also used to control the focus of aneyetracker camera to achieve desired focus conditions on the eye(s).FIG. 16 illustrates an exemplary camera focus control mechanism with aMEMS actuator used to control the distance L between the camera lensplane and the camera image sensor, in turn, providing control of thecamera focus distance D, in accordance with various embodiments. Forexample, FIG. 16 shows a camera focus control system 1600 for a camerathat has a conventional, rigid lens with fixed focal length F. An MEMSactuator 1601 controls an adjustable lens length L, 1602, between camerasensor 1603 and camera lens plane 1604, which in turn determines thefocus distance D, 1605, from camera lens plane 1604 to camera focusplane 1606. In this embodiment, both camera lens 1607 and the rear endof linear actuator 1601 are attached to eyefollower chassis 1608, i.e.,the eyefollower's fixed framework. The front end of linear actuator 1601is attached to camera sensor 1603, and the actuator's direction oftravel 1609 is along the camera's longitudinal axis Z, providing directcontrol of the camera lens length L, 1602, and ultimately allowingcamera 1600 to focus on eye 1610.

Note that the key direct variable to control when focusing a camera witha fixed focal length is the lens length L, 1602, between camera sensor1603 and camera lens plane 1604. In the focus-control embodiment of FIG.16, camera lens 1607 is fixed to eyefollower chassis 1602 and camerasensor 1603 moves with linear actuator 1601. In a mechanically differentbut functionally equivalent implementation, sensor 1603 is directlyattached the eyefollower chassis 1608, and the position of lens 1607 iscontrolled by actuator 1601.

As an alternative to a fixed-focal-length lens, an eyetracker camera mayalso employ a lens with variable focal length F. Variable-focal-lengthlenses include, for example, liquid, elastic and flexible lenses whoserefractive powers are adjusted by physically modifying the shape of thelens. In various eyetracking embodiments, variable-focal-length lensesare also controlled by MEMS devices.

FIGS. 17A and 17B show an example of a camera 1700 with a variable-powerlens 1701, whose variable focal length F, 1702, is controlled by a lenscompression ring 1703 that squeezes the lens material to increase thefocus power P and shorten the focal length F, in accordance with variousembodiments. In this embodiment, the lens length L, 1704, between lens1703 and sensor 1705 is constant, as illustrated in FIG. 17A. FIG. 17Bshows a front view of lens 1701 with lens compression ring 1703encircling the outer perimeter of the lens. A linear MEMS actuator 1706inserted in an opening of lens compression ring 1703 causes the ring toexpand or contract, in turn adjusting the power P of the lens.

Zoom Control

In various embodiments, MEMS may also be used to control the zoom of aneyetracker camera. As a user moves his head back and forth with respectto the camera's housing device, the zoom of the lens may be controlledto maintain a desired pixel resolution of the eye within the overallcamera image.

FIG. 18 illustrates an example of a lens 1800 with variable zoom, inaccordance with various embodiments. The zoom function of the lenstypically consists of the relative positioning of three (3) lenses: aconvex lens element E1, 1801, a concave lens element E2, 1802, andanother convex lens element E3, 1803. As illustrated in FIG. 18, lenselement E3, 1803, is fixed with respect to lens housing 1806, and lenselements E1, 1801, and E2, 1802, move relative to E3 along the lens'slongitudinal axis Z to achieve the variable zoom. The middle element E2,1802, typically moves over the whole range between the outer elementsE1, 1801, and E3, 1803. Element E1, 1801, typically moves over a muchsmaller range from its nominal position. Linear actuators 1804 and 1805move the lens elements E1 and E2 respectively. To effect these elementmotions, linear actuators 1804 and 1805 are each connected at one end tolens housing 1806 and at the other end to their respective lens elementsE1 and E2.

In various embodiments, a miniature eyetracking system includes a camerato image an eye, a microelectromechanical (MEMS) device to control theview-direction of the camera, and a processor. The processor receives animage of the eye from the camera, determines the location of the eyewithin the camera image, and controls the MEMS device to keep the camerapointed at the eye.

In various embodiments, the MEMS device controls a pan/tilt platform onwhich the camera is mounted.

In various embodiments, the MEMS devices are attached directly to thecamera.

In various embodiments, the MEMS device controls a pan/tilt mirror tosteer the camera view direction.

In various embodiments, the camera includes an open-center asymmetricaperture device that has a single transparent opening and a set ofopaque intrusion areas. An outer perimeter of the single transparentopening is inscribed in a circle and the set of opaque intrusion areasintrude into the outer perimeter of the inscribed circle.

In various embodiments, a method is provided to control theview-direction of a camera using a microelectromechanical (MEMS) device.An image is received from camera using a processor. A location of theeye is determined within the image using the processor. A MEMS device iscontrolled to keep the camera pointed at the eye using the processor.

In various embodiments, a miniature eyetracking system includes a camerato image an eye, a microelectromechanical (MEMS) device to control anadjustable focus of the camera, and a processor. The processor receivesan image of the eye from the camera, determines the focus condition ofthe eye image, and controls the MEMS device to maintain a desired focuscondition of the camera on the eye.

In various embodiments, the camera's lens has a fixed focal length F,the camera's focus condition is controlled by adjusting the distance Lbetween the lens plane and the camera sensor surface, and the MEMSdevice adjusts the distance L.

In various embodiments, the camera's lens has a variable focal length F,the camera's focus condition is controlled by adjusting the lens focallength F, and the MEMS device adjusts the lens focal length F.

In various embodiments, the camera includes an open-center asymmetricaperture device that has a single transparent opening and a set ofopaque intrusion areas. An outer perimeter of the single transparentopening is inscribed in a circle and the set of opaque intrusion areasintrude into the outer perimeter of the inscribed circle.

In various embodiments, a method is provided to control an adjustablefocus of the camera using a microelectromechanical (MEMS) device. Animage is received from camera using a processor. A focus condition isdetermined from the image using the processor. A MEMS device iscontrolled maintain a desired focus condition of the camera on the eyeusing the processor.

In various embodiments, a miniature eyetracking system includes a camerato image an eye, a microelectromechanical (MEMS) device to control anadjustable camera zoom, and a processor. The processor receives an imageof the eye from the camera, determines the size of the eye image withinthe overall camera image, and controls the MEMS to maintain a desiredsize of the eye image within the overall camera image.

In various embodiments, the camera includes an open-center asymmetricaperture device that has a single transparent opening and a set ofopaque intrusion areas. An outer perimeter of the single transparentopening is inscribed in a circle and the set of opaque intrusion areasintrude into the outer perimeter of the inscribed circle.

In various embodiments, a method is provided to control an adjustablecamera zoom using a microelectromechanical (MEMS) device. An image isreceived from camera using a processor. A size of an eye image withinthe image is determined using the processor. A MEMS device is controlledmaintain a desired size of the eye within the image using the processor.

While the present teachings are described in conjunction with variousembodiments, it is not intended that the present teachings be limited tosuch embodiments. On the contrary, the present teachings encompassvarious alternatives, modifications, and equivalents, as will beappreciated by those of skill in the art.

Further, in describing various embodiments, the specification may havepresented a method and/or process as a particular sequence of steps.However, to the extent that the method or process does not rely on theparticular order of steps set forth herein, the method or process shouldnot be limited to the particular sequence of steps described. As one ofordinary skill in the art would appreciate, other sequences of steps maybe possible. Therefore, the particular order of the steps set forth inthe specification should not be construed as limitations on the claims.In addition, the claims directed to the method and/or process should notbe limited to the performance of their steps in the order written, andone skilled in the art can readily appreciate that the sequences may bevaried and still remain within the spirit and scope of the variousembodiments.

What is claimed is:
 1. A camera, comprising: a plurality of illuminatorsto project light directly onto an object the camera is viewing; anobjective lens, wherein material is removed from the objective lens tocreate spaces for the plurality of illuminators, wherein the spaces arelens cutouts; and an asymmetric aperture device with opaque intrusionareas and one or more transparent regions, wherein the lens cutouts areincorporated into the objective lens of the camera at lateral locationscorresponding to locations of the plurality of illuminators, the lenscutouts permitting the plurality of illuminators to be located within aphysical volume of the objective lens, and wherein light reflected fromthe light projected directly onto the object and passing through the oneor more transparent regions acquires image features of the one or moretransparent regions that convey focus condition information about theobject.
 2. The camera of claim 1, wherein the asymmetric aperture deviceis embedded within the objective lens of the camera.
 3. The camera ofclaim 1, wherein the asymmetric aperture device is located out in frontof objective lens of the camera.
 4. The camera of claim 1, wherein theasymmetric aperture device is located behind the objective lens of thecamera.
 5. The camera of claim 1, wherein the asymmetric aperture devicecomprises multiple light illumination sources.